PSI - Issue 33

A. Sapora et al. / Procedia Structural Integrity 33 (2021) 456–464 Author name / Structural Integrity Procedia 00 (2019) 000–000

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phenomena (see for example Mindlin 1965 and Aifantis 1984, 1987, 1992). On the other hand, classical elasticity cannot describe problems dominated by microstructural effects, since their influence is not properly accounted by the standard continuum models. As for the gradient theory, there is a plethora of gradient-dependent constitutive equations that can be used to interpret size effects, i.e. the dependence of strength and other mechanical properties of the material on the size of the specimen (see for example Efremidis et al. 2001, Aifantis 2003). Moreover, for stress concentration problems, due the pronounced effect of microstructure, they have to be included, into the expression for the strain energy, some additional parameters characterizing the non-locality. This means that the state at a point depends also on the deformation state at neighboring points (Eringen et al. 1972, Eringen 1983, Kunin 1983). The first (or the second, etc.) gradient of the strain field may be considered as such an additional parameter because it characterizes spatial differences in elastic states at neighboring points. By including such non-local terms in the strain energy expression of a deformable elastic body, new modified constitutive equations appear and the relevant gradient theories are developed. Consequently, classical elasticity does not present any intrinsic length scale because it incorporates only the nearest neighbor interaction through the definition of the elastic strain energy density of a deformable body. An intrinsic length scale appears when the forces between particles are extended to include neighbor interactions. Thus, the gradient elasticity may be considered as a higher-order approximation of a fully non-local theory (Aifantis 1992, Askes and Aifantis 2011). The addition of higher order gradients in the governing equations takes into account: a) the non-locality of the physical state of the system in an approximate way, and b) the physical nature of the interactions between the smallest structural particles of the material. Concerning the gradient coefficients, which introduced phenomenologically, in conjunction with the gradient terms, it can be said that they characterize the influence (or the importance) of these terms into the solution of the problem (Aifantis 2003, 2020). Different criteria based on a critical distance have been proposed to assess the brittle failure behaviour of notched components over the last three decades (Taylor 2007), allowing to overcome the drawbacks rising from Linear Elastic Fracture Mechanics (LEFM). The basic assumption of these approaches is that failure takes place when either the punctual or averaged stress or an energy-related quantity at a finite distance from the notch tip reaches a critical value. Such a distance results a material constant, being proportional to l ch = ( K Ic /  c ) 2 , where K Ic is the fracture toughens and  c the tensile strength. Restricting his considerations to averaged approaches, Seweryn (1998) called these models nonlocal, being associated with assumption of the existence of a damage zone of finite length. However even these approaches could fail in predicting the fatigue strength of a cracked or notched structure having sizes comparable to the critical distance. This occurs due to the assumption that it is just a material constant, thus not able to interact with the geometry under investigation. In this context, in order to overcome these incongruences, the coupled criterion of Finite Fracture Mechanics (FFM) was then introduced (Leguillon 2002, Cornetti et al. 2006). The model requires for crack propagation the simultaneous fulfilment of two conditions: a stress requirement and the energy balance. Accordingly, the distance becomes a structural parameter, depending both on l ch and on the geometrical configuration. Thanks to its physically soundness and its efficiency, the criterion has been successfully applied to assess the strength of different materials, from polymers to ceramics, metals, rocks and composites, presenting different types of notch, and subjected to different loading conditions (see, for instance, Felger et al. 2017, 2019, Torabi et al. 2019, Sapora et al. 2020). It has been recently proved that FFM provides close predictions to the well-consolidated Cohesive Zone Model, once the constitutive law is properly defined (Cornetti and Sapora 2019; Cornetti et al. 2019: Doitrand et al. 2019). In the present contribution, GE and FFM predictions will be compared by referring to the geometry depicted in Fig. 1, i.e. a borehole under internal pressure p, looking for a connection between the two internal lengths. The circular hole under isotropic biaxial tension has already been faced both through GE (Chen et al. 2018) and FFM (Sapora and Cornetti 2018), taking into account the previous works by Suknev (2015, 2020), Torabi et al. (2017), and Sapora et al. (2018) (see, also, Matvienko et al. 2019). In order to corroborate the related results, experimental data referring to rock materials taken from the Literature (Cuisat and Haimson 1992) are successfully implemented.

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